1024 (number)

The neat coincidence that 2¹⁰ is nearly equal to 10³ provides the basis of a technique of estimating larger powers of 2 in decimal notation. Using 2^10a+b ≈ 2^b10^3a is fairly accurate for exponents up to about 100. For exponents up to 300, 3a continues to be a good estimate of the number of digits.

For example, 2⁵³ ≈ 8×10¹⁵. The actual value is closer to 9×10¹⁵.

In the case of larger exponents, the relationship becomes increasingly inaccurate, with errors exceeding an order of magnitude for a ≥ 97. For example:

${\displaystyle {\begin{aligned}{\frac {2^{1000}}{10^{300}}}&=\exp \left(\ln \left({\frac {2^{1000}}{10^{300}}}\right)\right)\\&=\exp \left(\ln \left(2^{1000}\right)-\ln \left(10^{300}\right)\right)\\&\approx \exp \left(693.147-690.776\right)\\&\approx \exp \left(2.372\right)\\&\approx 10.72\end{aligned}}}$

In measuring bytes, 1024 is often used in place of 1000 as the quotients of the units byte, kilobyte, megabyte, etc. In 1999, the IEC coined the term kibibyte for multiples of 1024, with kilobyte being used for multiples of 1000.

In binary notation, 1024 is represented as 10000000000, making it a simple round number occurring frequently in computer applications.

1024 is the maximum number of computer memory addresses that can be referenced with ten binary switches. This is the origin of the organization of computer memory into 1024-byte chunks or kibibytes.

In the Rich Text Format (RTF), language code 1024 indicates the text is not in any language and should be skipped over when proofing. Most used languages codes in RTF are integers slightly over 1024.

1024×768 pixels and 1280×1024 pixels are common standards of display resolution.

• Powers of 1024